APIS Bibliography

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Malcolm IA, Bacon PJ, Middlemas SJ, Fryer RJ, Shilland EM, Collen P. Relationships between hydrochemistry and the presence of juvenile brown trout (Salmo trutta) in headwater streams recovering from acidification. Ecological Indicators. 2014 ;37(Part B):351-364.

Wagg S, Mills G, Hayes F, Wilkinson S, Cooper D, Davies WJ. Reduced soil water availability did not protect two competing grassland species from the negative effects of increasing background ozone. Environmental Pollution. 2012 ;165:91-99.

Stockdale A, Tipping E, Fjellheim A, Garmo OA, Hildrew AG, Lofts S, Monteith DT, Ormerod SJ, Shilland EM. Recovery of macroinvertebrate species richness in acidified upland waters assessed with a field toxicity model. Ecological Indicators. 2014 ;37(Part B):341-350.

Battarbee RW, Shilland EM, Kernan M, Monteith DT, Curtis C. Recovery of acidified surface waters from acidification in the United Kingdom after twenty years of chemical and biological monitoring (1988–2008). Ecological Indicators. 2014 ;37(Part B):267-273.

Monteith DT, Evans CD. Recovery from acidification in the UK: Evidence from 15 years of acid waters monitoring. Environmental Pollution. 2005 ;137(1):1-177.

Berendse F, van Breeman N, Rydin H, Buttler A, Heijmans M, Hoosbeek MR, Lee JA, Mitchel E, Saarinen T, Vasander H, et al. Raised atmospheric CO2 levels and increased N deposition cause shifts in plant species composition and production in Sphagnum bogs. Global Change Biology . 2001 ;7:591-598.

Thurman EM, Malcolm RL. Preparative isolation of aquatic humic substances. Environmental Science and technology. 1981 ;15(4):463-466.

Jones L, Hayes F, Mills G, Sparks T, Fuhrer F. Predicting community sensitivity to ozone, using Elleberg indicator values. Environmental Pollution. 2007 ;146:744-753.

Jauhiainen J, Wallen B, Malmer N. Potential NH4+ & NO3- uptake in seven Sphagnum species. New Phytol. 1998 ;138:287-293.

Balaguer M, Valladares F, Ascaso C, Barnes JD, DelosRios A, Manrique E, Smith EC. Potential effects of rising tropospheric concentrations of CO2 and O-3 on green-algal lichens. New Phytologist . 1996 ;132:132, 641-652.

Sheppard LJ, Leith ID, van Dijk N, Leeson S, Mizunuma T, De Bakker R, Elustando DEV, Gomez HG. PK additions modify the effects of N dose and form on species composition, species litter chemistry and peat chemistry in a Scottish peatland. Biogeochemistry. 2013 ;116:39-53.

Manninen S, Woods C, Leith ID, Sheppard LJ. Physiological and morphological effects of long-term ammonium or nitrate deposition on green and red (shade and open grown) Sphagnum capillifolium. Environmental and Experimental Botany. 2011 ;72:140-148.

Elser JJ, Marzolf ER, Goldman CR. Phosphorus and nitrogen limitation of phytoplankton growth in the freshwaters of North America: a review and critique of experimental enrichments. Canadian Journal of Fisheries and Aquatic Sciences . 1990 ;47:1468-1477.

Stoughton JA, Marcus WA. Persistent impacts of trace metals from mining on floodplain grass communities along soda butte creek, Yellowstone National Park. Environmental Management. 2000 ;(25):305-320.

Wolff K, Morgan-Richards M, Davison AW. Patterns of molecular genetic variation in Plantago major and P. intermedia in relation to ozone resistance. New Phytologist. 2000 ;145:501-509.

Calvo E, Martin C, Sanz MJ. Ozone sensitivity differences in five tomato cultivars: visible injury and effects on biomass and fruits. Water Air and Soil Pollution. 2007 ;186:167-181.

Hayes F, Williamson J, Mills G. Ozone pollution affects flower numbers and timing in a simulated BAP priority calcareous grassland community. Environmental Pollution. 2012 ;163:40-47.

Niemi R, Martikainen PJ, Silvola J, Holopainen T. Ozone effects on Sphagnum mosses, carbon dioxide exchange and methane emission in boreal peatland microcosms. Science of The Total Environment. 2002 ;289:1-12.

Miller PR, Taylor OC, Wilbour RG. Oxidant air pollution effects on a western coniferous forest ecosystem. 1982 ;EPA-600/D:82-276.

Tipping E, Henrys PA, Maskell LC, Smart SM. Nitrogen deposition effects on plant species diversity; threshold loads. Environmental Pollution. 2013 ;179:218-223.

Maskell LC, Smart SM, Bullock JM, Thompson K, Stevens CJ. Nitrogen deposition causes widespread species loss in British Habitats. Global Change Biology. 2010 ;16: 671-679.

Goulding KWT, Bailey NJ, Bradbury NJ, Hargreaves P, Howe M, Murphy DV, Poulton PR, Willison TW. Nitrogen deposition and its contribution to nitrogen cycling and associated soil processes. New Phytologist. 1998 ;139:49-58.

Harmens H, Norris DA, Cooper DM, Mills G, Steinnes E, Kubin E, Thoni L, Aboal JR, Alber R, Carballeira A, et al. Nitrogen concentrations in mosses indicate the spatial distribution of atmospheric nitrogen deposition in Europe. Environmental Pollution. 2011 ;159:2852-2860.

Harmens H, Norris DA, Cooper DM, Mills G, Steinnes E, Kubin E, Thoni L, Aboal JR, Alber R, Carballeira A, et al. Nitrogen concentrations in mosses indicate the spatial distribution of atmospheric nitrogen deposition in Europe. Environmental Pollution. 2011 ;159:2852-2860.

Mills G, Pleijel H, Braun S, Buker P, Bermejo V, Calvo E, Danielsson H, Emberson L, I. Fernandez G, Grunhage L, et al. New stomatal flux-based critical levels for ozone effects on vegetation. Atmospheric Environment. 2011 ;45:5064-5068.

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